Power transmission mechanism



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A. D. PENTZ POWER TRANSMISSION MECHANISM yFiled Jan. 12, 1943 3 Sheets-Sheet l Aug. 7, 1945.v

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lPatented Aiug. 7, '1945" y 1 UNITED 4 "II`A'\I`ES. PATENT OFFICE V 2,381,712 l f rowaa TRANSMISSION MEclulNlsM n Albert D. Penn, New Ynrk, N. Y. Application January 12, 1943, Serial No. 472,118 v (cl. 74-1895) l i as claims.

My invention relates t power transmission and, more particularly, to

The Vpresent invention tion of, and, in part, an improvement on the invention forming the subject matter of my copending application, Ser. No. 421,530, filed December 4, 1941, now Patent No. 2,350,810, and includes all of the features described and claimed therein, butit embodies important additional features constituting an appreciable'advance overthe prior art, including my aforesaid prior invention. The general object of my prior invention is to create a power transmission which auto'- matically adjusts itself to the load, -effecting a.

' torque amplication whenthe driving torque is are retained in the presentinvention, but a number of additionalobiects are achieved by the present improvedtransmission. Thus, it is an object of the present invention-to permit a totalseparation of the low speed range from the direct drive range of the transliission, if and when so desired or when advisable according to circumstances. Another oblect is to reduce power losses` by increasing the efliciency of the transmission, more particularly inthe low speed rangeA and when operating in reverse.v 'A further object is to automatically shiftpower fromv the high speed mechanism to the low speed mechanism and back again, one.of the results vof such shifting-being a greater torque amplification. l Stili. another object .is to increase thel eflciency of the fluid coupling forming a part of the transmission, again, in the low speed range, with or without the addition of -an over-running ciutcl'l.4 It is also an object of the .present invention to produce a powertransmission wherein a true neutral position is `really andv fully materialized, and all undue drag on the .motor is eliminated. -It is a further object of the present invention to secure all of the above enumerated advantages by making a single change in the design of my aforesaid prior invention, namely. by breaking up the direct connection between the driving and the driven mechanisms into two parts and providing means for releasably locking the two parts together. A still further object is to make' the latter means semi-automatic and Ireafroxn the troubles of gear shifting. It is also is inpart, a continuasuch transmission in motor` l -I vehicles.

an object of the present invention to extend the feature of va direct drive in a state of slippage, available in my prior invention only for the forward drive, to include also the drive in reverse.l Other objects, not specifically mentioned above,

will become apparent vfrom the specification.

which follows and from the accompanying draw ings. 'However, before passing on to the specification, itis well to note that, in the present invenparts of the mechanism as are new and different from the mechanism disclosed in my aforesaid copending application, Serial No. 421,530, the other lparts being designated by numerals only to the extent necessary for their' proper identification.

In the drawings, Figure 1 is an'axial cross sec# tion of one embodiment of the present invention.

lFigure 2 is a cross section taken along the line 2`2 of Figure l. Figure ,3 is a cross section taken along the line 3 3 of. Figure 1. Figure 4 is a portion of a cross section similar to that shown in Figure 1, but for anotherA and preferred embodiment of the invention. Figure 5 is a cross section` taken along the line 5 5 of Figure 4. Figure 6 is a portion of a cross section similar to vthat shown in Figure 1 but for still another modiflcation of the device. Figure 7 is a cross section taken along the line 1--1 of Figure 6.

Referring to Figures 1-3 irl detail," I is the end of the drivingshaft of a motor vehicle, 2 is a shaft thereto, is a Sleeve.: of a skirt like fom. A aum coaxial with' the shaft l. o n the shaft'z. spllned coupling forms a part of the "transmission here illustrated, this fluid coupling comprising an imp'elle`r and two impelledmembers, one of the' latter being designated as a runner. The-impeller I is integral'with a hub 5' secured to the shaft I, asby screws 8, and is rotatable'about the shaft 2 on the sleeve 3, as on ball bearings shown but not numbered. The izmpellerA I is provided with blades 1. The runner 8, with its blades 9, is secured to the shaft Ithrough the connections Il with the flange Il) of the skirt likesleeve 3. The

third member of the fluid coupling; vthe impelied member i2 with itsblades I2, isvsecured to the flange I4 of a hollow shaft I6 coaxial with the` shaft 2- and rotatable thereon on ball bearings at one end and on a bushing at the other, neither one of said bearings being designatedI by numerals. The casing of the uid coupling is com- A pleted by the wall I8 which is sealingly secured to the impeller 4 at I1 and to the hollow shaft I5 at I8. To the casing of the fluid coupling is secured adrum |9 which is engageable by an elastic expansible member 28 of the type disclosed lin my aforesaid copending application, Ser. No. 421.530, and in another copending application, Ser. No. 465,187. In view of these complete and detailed prior disclosures, it is deemed unnecessary to describe the'member 20 in detail, except to say that, as here shown, it includes the peripheral segments and facing. The member 28 is splined to the shaft I6 through the intermediary of the rings 2| and 22 and the pins 22. The usual self starter ring gear is indicated at 28. The entire assembly comprising the fluid coupling is contained in a housing. 21 secured to lthe motor y.housing at 28'.v An over-running clutch 'is interposed between the two shafts 2 and. 15. This clutch-comprises an inner member 29 integral with the shaft 2, and an outer member 38 integral with the shaft `Iii, a set of rollers 2| being provided between the inner and the outer members. As will be later explained, this over-running clutch may be 'omitted from the device.

Passing now to the right of the fluid couplingA assembly, 24 is a hollow shaft secured to the ring 2|, as by bolts 26, coaxially with the shaft 2. To facilitate assembly, the shaft 2 is broken up into two parts.` coupled together at 26. A sun gear 22 of a planetary gear assembly is carried by the shaft 2. Freely rotatable on -the shaft 2 is a spindles 24. The pinions 26 are in mesh with the sun gear 22 and with a planetary ring gear to rotate on the shaft 86.` the-usual rollers 12 being intermediate the inner and the outer mem: bers of the clutch. The member 1| is outwardly cam shaped for engagement with yoke 12, a device disclosedinr detail in my aforesaid copending application, Ser. No.'421,530.A As in the former disclosure, the yoke 12 is pivoted at one end in the housing 28 for oscillation about a point 14 and, at the other end, 16, linked to a piston forming a part of a hydraulic control device. The outer member 1I of the over-running clutch is pro- 66. On the end of shaft-61 spider 22 in which are .iournalled pinions 25 on l 26 supported on and freely rotatable on ball bearings in ring 21, the latter forming a part of the housing 28. The spider 22 has annular teeth 28 which are ensageable with the teeth 48 of a clutch 4| slidably splined on the hollow shaft 24. In the clutch 4| is a groove 42 to receive pins or rollers 42 extending from an arm 44of a hollow tube 46. In the hollow tube 46 is a rod 46 secured to the tube 46 as by pins 41.- Another varm 48 is-secured to the rod 46 by a pin 49. The arm 48, a manually operated rod 68,A and alink 6|., are

vided with an annular row of teeth 16 engageable by the teeth 62 of the sliding clutch 6|. .A

planetary ring gear 11 is bolted to a pair of discs 18 and 19, the disc 18 being rotatably carried on shaft`68, andjthe disc 19. being rotatably carried on the end cover 88 of the housing 28. The disc 18- is provided with an annular row of teeth 8| engageable with the teeth 62 of the sliding clutchill, A sun gear .82 is splined to the hollow shaft 6 6.' Pinions 82 are journalled in spiders 84 and 85, 84 being splined to shaft'61, and spider 85 being rotatably supported on shaft is theusual anged driven member 86.

Latching means are provided for securing the transmission in four positions, namely, two forward, one neutral and one reverse, similar to the means illustrated in Figure 1 of my copendingv application, Ser. No. 421,530. Three of these four positions are indicated in Figure 1 of the present application by dash-dot lines.

In Figure 4 is `shown another arrangement for connecting thedriven shaft to the impelled member |2. and disconnecting Vthisshaft fromthe impelled member. This is the arrangement which I prefer because of its semi-automatic nature and because it does away with the use of gear' shifts. Instead of, the teeth 29 on the spider 32, we have now a projection or boss 98 extending from the spider 22 and provided with a latch stop f pin 9|. Pivoted in the boss^98, at 92, isa threefingered member 92, the ngers being designated by the numerals 94, 95,96. A double acting tension spring 91 itis attached to the boss 98 at a fixed point 9 8` and at a point 9 9 off the central line 92-98. The shaft 24 has three slots |88,

pivotally connected as by a pin 62. 'I'he link 5| -is pivotally connected, as through a pin'62, to another arm u. The arm sus nxed to a shaft 55, r

, 66,` 8l, vto prevent rotary motion of the clutch 6|. On the shaft 61 is splined a spider 88 forming another set of bearings for the spindles 24 of the pinions 26. 'I'he hollow shaft 68 is connected to the planetary ring gear 28 as by bolts' 69.

The device is'provide'd with an over-running clutch having an .innermember 18 integral with the hollow shaft-66 andan outer member 1| free |8|, |82, engageable by the iingers 96. A movable ring |82, mounted in the housing 28 .in the ,same manner as the sliding clutch 6| in Figure 2, except that the ends |84 of the pins 64V are now squared' to prevent the ring |82 from deviatingl from its vertical position, is operated by the arm 44 to press upon the fingers 94. The parts shown in Figure'4 in full lines correspond to the neutral position of the transmission. When thering |82 reaches the positionpartly indicated in dotted'v lines, the trigger action .of themember 92 will cause the fingers 98 to enter the slots |88, |8| and In vFigure 6 is showma modincation of the arrangement provided by the clutch 6|". In this case, there is no over-running clutch 18, 1|, 12,

but a drum like member |86 integral with the `shaft 86, having a cam shaped outer surface |86.

The member is provided with teeth |81 takingfthe pla of the teeth 16 in Figure 1. In the present modification, two one way clutches are provided in lieu of-the over-running clutchv 18, 1|, 12, one for the forward phase of the transmission, and the other' for the reverse phase. The two clutches have a common outer member |88, but

separate inner. members |89 and |I8. Themem-" 7 5 ber |09 has teeth m engageable with thl teeth ...u .mmmu wmm mmmwmmmmmmmm1-m am. m.. mmm... ..wm. mmmwmmw.m.mmmmmwwmmmmwmmmm mmwmmw mn. wmmmw Mmmm.. .mwwwf m... .Wmmmwwmmmmummmmmmm ...mh m -mum .1 @www M mnmtmm mwmmm'um @Mmmm mmmtmmm .mmmxmmmmmmmmmmmmmwmmmmm @mm Mmmm mmmmmmmmmmmm.mmmwmmmm mm. @mi d.. .am mmw... .M umwrm n.mmmmm ....xwmmmm wwmmmmax .mm m msmmm WMJ....mmmmmmwm M wnumumw a Mmmm Mmmm wm. u... man@ mmam ...mwmmmmdm mmmmwmmmmm .mmmmwmmmmms.. n Mmmm.. mmmmmmmw mmmwwmmmmmmwmmm Wundmmmmm. wmmwmmmmwm.. M ,.mmmmmw ...www mmmmwmmm mmmmmmmmmmmm .w www mwwmmmwmmmmwmmmmm wwmmmmmmmmwwm Mmmm f. ma; .......wmw nhmmmm wzmmmwmmuwmmmmm ....mmmunmwwmmmmumm. )w @ummm mmmmmmwmu Mmmm .Hm m mm @www .Mmm ,.....mw.., M www ....m mnsumwemmm mm Mmmmmfw .v msm# .mmmmmmm mmmwmumw w hmmm ...Mmmm mmutmmmnmmmm m n m....mwmm.. mma ....Wummrdm mmfkuwwmm mm m... udtmm ...uw m., mm m m Wmwmm-. @..Ww m. Mw. mm. @mmm mm Mmmmmmwwmmmmmmmmmmmw www wmmmmmmmmmmm umm... W ummm mm.. mmrmm .mw, m ...ummm mummummm .mwpuj .un mh@ um Mmmm m m m m ,m m "4 ...M.-.m.m mw.. m umm www .maw M Mmm m www u ...www m mm mmf. @Marmwm n wmmmmwwmmwummw um www .mmmmwmxmwMmmmmmmrwmmmwmxw u wm... m ...www m .m s w.. m ...i @www ma mmm m w, m um Muwhm m u mm mgmfam mmmmm memwmmmmmnnm wmummmmemmm mmmmawm mm mmnmmnmmnmxnmu my.. m M Memmhmh f www m5 www. ,m. ...M mmmww.. u n o than the slot Ill. This is done to make sure that at least one of the lingers It will freely enter a slot. after which the other fingers will fall in more easily. When the fingers It have entered the slots in the shaft 24. the fingers Il will have moved to positions abutting the ring III on the right side. When. therefore. the rod l0 is moved back. i. e.. to the left in the iigure. the ring lll will press the fingers Il away from the vertical until the action of the eccentrically mounted springst1 forces the threefingered member Il to turn clockwise, thereby extricating the lingers Il from the slots in the shaft Il and unlocking this shaft from the driven shaft Il.

While the principle-of operation of the clutch 4| and the one illustrated in Figures 4 and 5 is the same. it will be noted that the locked condition of the shafts l( and Il. in one case. corresponds to the half way engagement of the teeth Il and Il of the clutch Il. and the unlocked condition of these shafts to the complete engagement of these teeth while, in the other case, the locked condition of the two shafts corresponds to the complete engagement of the teeth Il and 1l, and the unlocked condition to the half way enssement of these teeth.

Going back to ligure i, to put the transmission in reverse, the rod Il is moved to the left. effecting engagement of the' teeth l! and lll and discrimina the clutch il. In so far as the operation of the clutch ll is concerned, it is identical withl that disclosed in my copending application. 8er. No. 421,530, but ...difference ofoeifect here owing to the unlocking of the shafts and l1 fromone another. The effect of this 1r amines amused wim-one way dem m. iss.' ma In.' m. me em shaped 'beingvformed to actin opposite 'cam surfaces are shown missionatalowspeed0n1y,ummypr1r gp. plication. Ber. No. 421.530, the new arrangement shown in Figures 6 and 7 provides a range of speeds as wide as that for the forward phase, except only the 1:1 direct transmission without slippage eifectd in the forward phase when all the driving and driven parts of the ton are locked together for rotation as a unit.

The operation may be further illustrated as applied to the case of a motor vehicle. As in my former repeatedly referred to ton. it automatically adjusts itself to the load on the driven shaft. Consider the operation starting from rest. The transmission is in its neutral phase. The impeiled member I 2 and driven shaft il are disconnected. To start the vehicle in the forward direction, the rod 60 is moved to the right until the teeth il! of the one way clutch llll--illl are engaged all the way (when the type illustrated in Figure l is used) or half way (when the type illustrated in Figure 4 is used). This leaves the impelled member i! disengaged from the shaft Il. The tron now operates through the first planetary gear mechanism, at a low speed but high torque. The sun gear l2 rotates with the shaft I in the forward direction, causing the pinions Il to rotate in the reverse direction about their spindles Il, the latter being momentarily held stationary by the inertia of the vehicle at rest. 'Ihe initial impact on the ring gear Il by the pinions 8l is in the reverse direction, and this initial impact is communicatedto the member lil of thelone way eluteh ila-llt through the engaged teeth Ill and III, locking therclutoh and thereby holding the ring gear t0 against rotation. With the ring gear held stationary, the pinions 8l will rotate around the sun gear l2 at a low speed which will gradually increase. as will be clear from the next step in-the operation. At this time. i. e..

'aftertheshaftllhasbeencausedto'rotateat the low speed. the impelled member i2 is connected to the shaft Il by movingthe rod Il further to the right until the teeth il! .ndlll are engaged all thev way (when the type of clutch showninl'iguresiandisusedlormovingthe rod Il baokuntll theteeth Il! and Ill areonly half way engaged (when thetypeof clutehshown infFigure'i is used). 'l'.'he ioint action of the direct'power transmission from the now engaged pelled member i2 to the shaft il. together withlthe action of the indirect transmission .through the nrst planetary gear mechanism.

eausestheshaft IItorapidlyincrea'seinspeed ofA rotation. and this joint action will cause the mieli' Sltobereleasedforrotationinthe forward direction, also releasingthelockonthe one way clutch Ill-Ill. Thus. the transmission automaticallypasses from its low speed. hightomue phasetoitshlghspeedphss'ewith, however, some slippage in part due to slippage. inthe duid coupling. From this stage of high speed transmission with slippage the transmls sion, again automatically, passes into direct 1:1

transmission without slippage through the action o oftheeentrlfugalclutchllinthemannerfully disclosed in my oopending application. Ber. No. 21,580. and. therefore. not further discussed re. :'Iostartthevehicleinthereversedirection from rest (shifting the transmission from one directiontotheoneoppositeisalways aooorn- Dlishedbyrltb-Dlmthevehicletort. with thetransmlssioninitsneutralphlse),therodil imovedtotheleft untiltheteethllareenpendulous yoke gaged with the teeth li. This leaves the impelled member il and clutch Il disconnected from the shaft I'I. The ring gear It and the shaft II secured to the ring gear It through the member I", are now rotating in reverse. 8o. also, is the sun gear l! mounted on the hollow shaft It. The pinions I3 rotate in the forward direction on their splndlies. The initial impact on the ring gear 11 is in the forward direction. which is communicated to the member I" of the one way clutch III-III through the engaged teeth Iii and Ii, locking this clutch and thereby holding the ring gear 11 against rotation. With the ring gear 11 held stationary. the pinlons Il rotate in the reverse direction around the sun gear Il. driving the shaft t1 in the reverse direction. As the speed of rotation of the hollow shaft il increases. the ring gear 11 is released for rotation in the reverse direction, at the same time unlocking the clutch ill-ill. whereupon the rotation of the shaft I1 will proceed at a gradually increasing speed .until it reaches the speed of the slippage allowing direct transmission, but in the reverse direction. The transition from low speed, torque amplified transmission to direct, slippage allowing transmission at high speed, as in the case of the transmission in the forward direction, proceeds automatically.

When shifting the transmission from the neutrai phase to one or the other ofthe drive phases, it is necessary to hold the teeth 1t in Figure l. or the teeth Ill in Figure 6 against rotation. When this is done.'the teeth Il will be held against rotation. as will be presently explained. In Figures l and 2,' the mechanism for doing this is identicall with the one described in my copending application. 8er. No. 421.530, and illustr-iited therein Figures 5-7. When the arrangement shown in Figures 8 and 'f of the present application is adopted, a similar mechanism is employed. the only dinerence being that the 18 now embraces the cam shaped surface Ill of the member Ill, instead of the cam shaped outer surface -of the over-running clutch lI-II of Figure i. It is not necessary, therefore to go into a detailed description and operation of the device.

As to the teeth Il, which must remain stationary when the transmission is shifted into reverse. they meet this requirement for the following reason. When the teeth 1I are heid against rotation in ligure i. this is accomplished by holding the clutch .nember Il stationary; when the teeth ill are held against rotation in Figure 6. this is accomplished by holding the member ill stationary. In either case, this will hold the hollow shaft Il against rotation. and since the. sun gear I! is mounted to rotate with the shaft the sun gear I! is now held'against rotation. The vehicle' being at rest, the spindles of the pinions Il are also `held stationary, so that these pinions can not rotate either about their spindles or around the sun gear Il. Consequently. the ring gear 11 is now held against rotation, and. therefore, the teeth BI also are so held.

It is desired to again emphasise the fact that in the present type of transmission. owing to the feature of selective engagement and disengage ment of the shaft -ll and the impelled member Il, to and from the driven shaft l1. there is no undue drag on the motor. When the transmission is in its neutral phase. the impelled member blades. being disconnected from the shaft l1. are not held stationary by the inertia of the vehicle at rest and, therefore. they do not offer any resistance to the rotation of the impelle! blades. It will be noted. also. that the impelled member blades, during the reverse phase of the transmission, do not turn in the reverse direction with the shaft Il from which they are disengaged. It is also desired to emphasize the unique feature of the abilityof transferring the functions of the impeller and of the centrifugal clutch whenever desired from their normal direct drive range to the emergency low speed. high torque range. and back again to their normal functions. This and other novel features of the present transmission endow it with a high degree of flexibility and ready adaptability to various conditions which it is not possible to meet in transmission mechanisms in use today.

The various details of construction shown are not to be understood as intended to limit the scope of the invention, mamy variations, additions and omissions being possible without in any way affecting the principles involved or the application of these principles as herein illustrated.

I claim:

l. A power transmission mechanism compris- 'ing means for transmitting a portion of said power directly from a driving shaft 'to a driven shaft, means for transmitting the remainder of said power through a torque multiplying mechanism, and means for bodily transferring said power portion from said direct transmitting means to said torque multiplying mechanism and back again.

2. In a power transmission mechanism, means for transmitting power from a driving shaft to a driven shaft, including a fluid coupling, the latter comprising animpeller actuated by said driving shaft. at least one impelledmember, releasable means for directly connecting said impelled member with said driven shaft, and means for changing the function of said impelled member to that'of an impeller when said impelled member is disconnected from said driven shaft.

3. In a power transmission mechanism, means for transmitting power from a driving shaft to a driven shaft, including a fluid coupling, the latter comprising an impeller actuated by said driving shaft, at least one impelled member. releasable means for directly connecting said impeiled member with said driven shaft, and means. responsiveto centrifugal forces generated by the notation of said impelled member when it is disconnected from said driven shaft for changing the function of said impelled member to that of an impeller. y

4. A power transmission mechanism according to claim 2 wherein the means releasably connecting the impelled member with the driven shaft comprise a clutch slldable parallel to the axis of the mechanism and provided with teeth. and teeth fixedly connected with s aid driven .shaft for engagement with s aid` clutch teeth. f

5. A power transmission mechanism according to claim 2, wherein the means for-releasabiy conand releasable locking means including a spring actuated member adapted to engage said slots by a trigger action.

7. A power transmission mechanism according to claim 3, wherein the last mentioned means comprise a centrifugal clutch operative between the impelled member and the driving shaft.

8. A power transmission mechanism according to claim 3, wherein the last mentioned means comprise a drum, means locking said drum to the driving shaft, and an elastic expansible member connected to the impelled member for frictional engagement with said drum.

9. In a power transmission mechanism, means for transmitting power from a driving shaft to a driven shaft. including a fluid coupling, the latter comprising an impeller and members impelled thereby, and driving connections between said impelled members and said driven shaft, one of said connections being direct and releasable without releasing the other connections.

l0. A power transmission mechanism according to claim 9, wherein the last mentioned means comprise a clutch slidable parallel to the axis of the mechanism, teeth on said clutch, and teeth fixedly connected with said driven shaft for engagement with said clutch teeth.

l1. A power transmission mechanism according to'claim 9, wherein the last mentioned means comprise anextension member connected to and rotating with the impelled member, an extension member connected to and rotating with the driven shaft, and releasable locking means between said extension members.

12. A power transmission mechanism according to claim 9, wherein the last mentioned means comprise a sleeve connected to and rotating with the impelled member, slots in said-sleeve, and releasable locking means including a spring actuated member adapted to engage' said slots by a trigger action.

13. In a power transmission mechanism, means for transmitting power from a driving shaft to a driven shaft, including a speed rate changing mechanism and a fluid coupling, the latter comprising an impeller and members impelled thereby, one of said impelled members being operatively connected with said speed .rate changing mechanism, and a second impelled member being releasably connected to said driven shaft for direct transmission of power thereto, and means for transferring said last mentioned power to said speed rate changing mechanism when said second impelled member is disconnected from said driven shaft.

i4. A power transmission mechanism accordingto claim 13, wherein the-last mentioned means comprise an over-running clutch operative between the two impelled members. y

l5. In a power transmission mechanism, means for transmitting power from a driving shaft to a driven shaft, including a speedrate-changing mechanism and a fluid coupling, the latter comprising an impeller actuated by said driving shaft, an impelled member, means releasably connecting said impelled member with said driven shaft, a runner intermediate said impeller and said impelled member operatively connected with said speed rate changing mechanism, an intermediary shaft actuated by said runner, a sleeve on said intermediary shaft rotatable with said impelled member, and an over-running clutch between said sleeve and said intermediary shaft for causing the power transmitted by said impelled member to be transferred to said intermediary shaft when said impelled member is disconnected from said driven shaft.

16. In a power transmission mechanism, means for transmitting power from a driving shaft to a driven shaft, including a fluid coupling, the latter comprising an impeller and members impelled thereby, connections between said impelled members and said driven shaft, one of said connections being direct and releasable without releasing the other connections with said driven shaft, means for controlling said releasable connection, means for shifting the transmission from its neutral phase to a driving phase in one or the opposite direction, and means for jointly operating said control means and shifting means.

`1'?. A power transmission mechanism according to claim 16, wherein the last mentioned means comprise a rock shaft associated with said control means and a rock shaft associated with said shifting means and a. linkage between said rock shafts, and means operable at a remote .point for actuating said linkage.

18. A power transmission mechanism according to claim 16, wherein said control means and said shifting means are sidable simultaneously and in the same direction parallel t'o the axis of the mechanism, the connection between the impelled -member and the driven shaft being established when the said shifting means is half way along its sliding range, and the connection being severed when said shifting means is at the end of its sliding range or entirely out of it.

19. In a power transmission mechanism. means for transmitting power from a driving shaft to a driven shaft, including a planetary gear assembly for transmission in one direction, a 'one way clutch associated with said planetary gear assembly for controlling the transmission in said direction, a second planetary gear assembly for transmission in the opposite direction, a one way clutch associated with said second gear assembly for controlling the transmission in said opposite direction, and means for selectively engaging one orv the other of said one way clutches with the planetary gear assembly with which it is associated.

20. In a power transmission mechanism, means' for transmitting power from a driving shaft to a driven shaft, including a planetary reduction gear assembly, a planetary ring gear forming a part of said gear assembly, a clutch having a member free to rotate in one direction only, said clutch member being engageable with said planetary ring gear for rotation therewith. a second planetary gear assembly, a ring gear forming part of said second gear assembly. a second clutch having a member free to rotate in one direction only opposite to the direction in which said first mentioned clutch is free to rotate, the rotatable member of said second clutch being engageable with the ring gear of said second planetary gear assembly, and means for selectively establishing engagement of one or the other of said rotatable clutch members with the corresponding ring gear of said planetary gear assemblies.

2l. A power transmission mechanism according to claim 20, wherein the last mentioned means comprise teeth on the rotatable clutch members, teethon portions of the mechanism secured to the planetary ring gears, and means for selectivelyengaging the teeth of one or the other of said rotatable clutch members with the teeth of the portion of the mechanism secured to the corresponding planetary ring gear.

22. In a power transmission mechanism. means for transmitting power from a driving shaft t a driven shaft, including a fluid coupling. the latter comprising an impeller actuated by said driving shaft, and impelled members, one of said impelled members being reieasably connected with said driven shaft, a reduction gear assembly fOr transmission in one direction, a one way clutch associated with said reduction gear assembly, a second reduction gear assembly for transmission in the opposite direction, a one way clutch associated with said second gear assembly. means for operating the connection between said driven shaft and the impelled member releasably connected thereto, and means for selectively engaging one or the other of said one way clutches with the reduction gear assembly with which it is associated. the last mentioned means being operable jointly with said means for operating the connection between the driven shaft and the impelled member releasably connected thereto.

23. In a power transmission mechanism, means for transmitting power from a driving shaft to a driven shaft. including a fluid coupling, the latter comprising an impeller actuated by said driving shaft and impelled members, one of said impelled members being releasably connected with said driven shaft, a planetary gea-r assembly for transmission in the reverse direction, a ring gear forming a part of said gear assembly, a clutch having a member free to rotate in said reverse direction only and engageable with said ring gear', and means disconnecting said impelled member from said driven shaft when engagement of said rotatable clutch member with said ring lei-l' i8 entcted.

24. In a power transmission mechanism. means for transmitting power from a driving shaft to a driven shaft, including a speed, rate changing mechanism and a fluid coupling. the latter compxising an impeller actuated by said driving shaft. and impelled members, one of said impelled members being operatively connected with said speed rate changing mechanism. and a second impelled member. being relea'sably connected with said driven shaft for direct power transmission thereto, means for causing said two impelled members to rotate as a unit when said second impelled memberis disconnected from said driven shaft,

and means for establishing a direct power transmission without slippageA from said driving shaft to said speed rate changing mechanism when the rotation of said unit attains a predetermined speed.

25. In a power transmission mechanism. means for transmitting power from a driving shaft to a driven shaft, including a speed rate changing mechanism and s fluid coupling. the latter comprising In impeller actuated by said driving shaft, an impelled member, means releasably connecting laid impelled member with. said driven shaft, a runner intermediate said impeller and said impelled member operatively connected with said speed rate changing mechanism. an intermediary shaft actuated by said runner, a hollow shaft around said intermediary shaft coaxial therewith and rotatable with said impelled member, an overrunning clutch between said intermediary shaft and slid hollow shaft for causing the two last mentioned shafts to rotate as a unit when said impelled member is disconnected from said driven shaft, and a centrifugal clutch operative when the 26. A power transmission mechanism according to claim 25, wherein the centrifugal clutch inciudes an elastic expansible element, and a member secured to the driving shaft engageable by said expansible elment.

27. In a power transmission mechanism, means for transmitting power from a driving shaft to a driven shaft, means for reversing the direction of the transmissions clutch cooperating with said reversing means, a member engageable by said clutch having a cam shaped outer surface. means for holding said member against rotation while shifting the transmission, said last men` tioned means comprising a pendulous .Yoke embracing said cam shaped surface. whereby said member can rotate only when said yoke is free to oscillate, and means for controlling the oscillation of said yoke.

28. In a power transmission mechanism. means for transmitting power from a driving shaft to a driven shaft, including a planetary gear mechanism, a ring gear forming a part of this planetary gear mechanism, means for reversing the direction of the transmission, a member rotatable with said ring gear having a cam shaped outer surface, means for holding said member against rotation while shifting the transmission. said last mentioned means comprising a pendulous yoke embracing said cam shaped surface, whereby said ring gear can rotate only when said yoke is free to osciilate. and means for controlling the oscillation of said yoke.

29,. In a power transmission. means for transmitting power from a driving shaft to a driven shaft, including a set of engageable elements for driving said driven shaft in one direction when said elements are in engagement, another set of engaieable elements for driving said driven shaft rotation of said unit" attains a predetermined speed. for establishing a direct 1:1 transmission from said driving shaft to said speed rate changing in the opposite direction when theelements of said other set are in engagement. aclutch for controlling the shifting of the enmeinent from one to the other of said sets of elements and their disengagement, a fluid coupling comprising an impeller and members impelled thereby. driving connections between said impelled members and said driven shaft, one of said connections bdng direct and releasable without releasing the other connections; a clutch for controlling laid releasable connection. and means for jointly operating said clutches. v

30. In n. power transmission from a driving shaft to a driven shaft. means for driving said drivenshaftinthesameorintheoppositedirection to that of said ,driving shaft. including n. fluid coupling comprising an impeller and members impelled thereby, driving connections between said impelled members and .id driven shaft. one o! said connections being 'direct and' re'leasabie without releasing the other connections, and means for selectively holding said impelled member connected to or disconnected from said driven shaft while said driven shaft rotates in the same direction as said driving shaft.

31. A power transmission mechanism according to claim 30, wherein the second clutch includes an extension member secured to and ro- .tating with the impelled member and a spring actuated-member secured to said driven shaft and agipted to engage said extension member by s trigger action, while the rst clutch is sliding parallel to the axis of the mechanism, the connection between the impelled member and the driven shaft being established when said first .n ciutchisatthecndofitsslidingrange,andbeing severed when said first clutch is half way alon its sliding rang'e or entirely out oi' it.

32. In a power transmission from a drivin! shaft to a driven shaft. means for drivina Said driven shaft in the same or in the 099061te dira' tion to that of said driving shaft. includin! a fluid coupling comprising an impeller and members impelled thereby. driving connections between said impelled members and said driven shaft. one of said connections being direct and releasable without releasing the other connections, and means for holding said impelled member out of connection with said driven shaft while said driven shaft rotates in said opposite direction.

33. A power transmission from a driving shaft to a driven shaft. including a fluid coupling, the latter comprising an impeller actuated by said driving shaft. an impelled member and an intermediate runner. both actuated by said impelier, releasable means for transmitting the power input of said impelled member directly to said driven shaft. means for transmitting the power input of said intermediate runner to said driven shaft through a torque multiplying mechanism. and means for transferring the power input of said direct transmission means to said torque multiply'mg mechanism and back again.

34. A mechanism for transmitting power from a driving shaft to a driven shaft. including a fluid coupling. the latter comprising an impelier actuated by said driving shaft. an impelled member and an intermediary runner, both actuated l-y said impeller. means for transmitting a portion of said power from said driving shaft directly to said driven shaft, means for' transmitting the reated by said driving shaft. an impelled member and an intermediary runner. both actuated by said impeller. relensable means for directly connecting said impelled member with said driven shaft. means connecting said intermediary runner with :am dnven smut through s remue muitiplying mechanism. and means for changing the function of said impelled member to that of said intermediary runner when said impelled member is disconnected from said driven shaft.

36. A mechanism for transmitting power from n driving shaft to a driven shaft. including a fluid coupling. the latter comprising an impeller actuated by said driving shaft. an impelled member and an intermediary runner. both actuated by said lmpeller. releasable means directly connecting said impelled member with said driven shaft. means connecting said runner with said driven shaft through a torque multiplying mechanism. and means for bypassing said duid coupling and establishing a direct 1:1 driving connection between said driving shaft and said torque multiplying mechanism by disconnecting said impelled member from said driven shaft.

37. A mechanism according to claim 36. wherein the means for bypassing the fluid couming and establishing a direct 1:1 driving connection between the driving shaft and the torque multiplying mechanism includes a centrifugal clutch operative between the impelled member and the driving shaft.

38. In a power transmision. a driving shaft, a driven shaft. a torque multiplying mechanism. means for simultaneously transmittingv power from said driving shaft to seid driven shaft directly through a releasable connection between said two shafts and directly through said torque multiplying mechanism. and means for causing the power transmittsble through said releasa'ble connection to be diverted to said torque multiplying mechanism when said relessable connection is released.

ALBERT D. PENTZ.

CERTIFICATE OF CORRECTION.

Patent No. 2,581,772.

ALBERT D.

It is hereby certified that error appears in the printed specification Angus t I 19lt5.

PENTZ of the above numbered patent requiring correction as follows: Page 7, second column, line 65, claim 51, for the claim reference mmersl read "29": directlyP-g page 8, second column, line 5?.-claim 58. for "directly" read- --inand that the said Letters Patent should be rend with this correction therein that me seme may conform to the record of the oase in the Pa tent Office signed and sealed uns 15th day of Novem, A. D. 19ii5.

(Seal) Leslie Frazer First assistant cmusioner er Patents.

severed when said first clutch is half way alon its sliding rang'e or entirely out oi' it.

32. In a power transmission from a drivin! shaft to a driven shaft. means for drivina Said driven shaft in the same or in the 099061te dira' tion to that of said driving shaft. includin! a fluid coupling comprising an impeller and members impelled thereby. driving connections between said impelled members and said driven shaft. one of said connections being direct and releasable without releasing the other connections, and means for holding said impelled member out of connection with said driven shaft while said driven shaft rotates in said opposite direction.

33. A power transmission from a driving shaft to a driven shaft. including a fluid coupling, the latter comprising an impeller actuated by said driving shaft. an impelled member and an intermediate runner. both actuated by said impelier, releasable means for transmitting the power input of said impelled member directly to said driven shaft. means for transmitting the power input of said intermediate runner to said driven shaft through a torque multiplying mechanism. and means for transferring the power input of said direct transmission means to said torque multiply'mg mechanism and back again.

34. A mechanism for transmitting power from a driving shaft to a driven shaft. including a fluid coupling. the latter comprising an impelier actuated by said driving shaft. an impelled member and an intermediary runner, both actuated l-y said impeller. means for transmitting a portion of said power from said driving shaft directly to said driven shaft, means for' transmitting the reated by said driving shaft. an impelled member and an intermediary runner. both actuated by said impeller. relensable means for directly connecting said impelled member with said driven shaft. means connecting said intermediary runner with :am dnven smut through s remue muitiplying mechanism. and means for changing the function of said impelled member to that of said intermediary runner when said impelled member is disconnected from said driven shaft.

36. A mechanism for transmitting power from n driving shaft to a driven shaft. including a fluid coupling. the latter comprising an impeller actuated by said driving shaft. an impelled member and an intermediary runner. both actuated by said lmpeller. releasable means directly connecting said impelled member with said driven shaft. means connecting said runner with said driven shaft through a torque multiplying mechanism. and means for bypassing said duid coupling and establishing a direct 1:1 driving connection between said driving shaft and said torque multiplying mechanism by disconnecting said impelled member from said driven shaft.

37. A mechanism according to claim 36. wherein the means for bypassing the fluid couming and establishing a direct 1:1 driving connection between the driving shaft and the torque multiplying mechanism includes a centrifugal clutch operative between the impelled member and the driving shaft.

38. In a power transmision. a driving shaft, a driven shaft. a torque multiplying mechanism. means for simultaneously transmittingv power from said driving shaft to seid driven shaft directly through a releasable connection between said two shafts and directly through said torque multiplying mechanism. and means for causing the power transmittsble through said releasa'ble connection to be diverted to said torque multiplying mechanism when said relessable connection is released.

ALBERT D. PENTZ.

CERTIFICATE OF CORRECTION.

Patent No. 2,581,772.

ALBERT D.

It is hereby certified that error appears in the printed specification Angus t I 19lt5.

PENTZ of the above numbered patent requiring correction as follows: Page 7, second column, line 65, claim 51, for the claim reference mmersl read "29": directlyP-g page 8, second column, line 5?.-claim 58. for "directly" read- --inand that the said Letters Patent should be rend with this correction therein that me seme may conform to the record of the oase in the Pa tent Office signed and sealed uns 15th day of Novem, A. D. 19ii5.

(Seal) Leslie Frazer First assistant cmusioner er Patents. 

